CN113987630A

CN113987630A - Method and system for carrying out statistics on engineering quantity of polyurethane heat-insulating layer of racetrack by using BIM

Info

Publication number: CN113987630A
Application number: CN202111204627.5A
Authority: CN
Inventors: 樊琼; 刘卫健; 刘莎莎; 韩啸; 黄�俊; 张明荣
Original assignee: Shanghai Baoye Group Corp Ltd; Shanghai Baoye Metallurgy Engineering Co Ltd
Current assignee: Shanghai Baoye Group Corp Ltd; Shanghai Baoye Metallurgy Engineering Co Ltd
Priority date: 2021-10-15
Filing date: 2021-10-15
Publication date: 2022-01-28

Abstract

The invention provides a method and a system for carrying out statistics on the engineering quantity of a polyurethane heat-insulating layer of a racetrack by using BIM. The method comprises the following steps: modeling the track according to a layered modeling mode to obtain a track model; layering heat preservation layers of the track model and endowing materials to the layers of the heat preservation layers; adjusting the thickness of the heat-insulating layer model at the polyurethane mortar support column according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the racetrack; and carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer. According to the method, the racetrack is modeled, the heat preservation layer is layered, materials are given to each layer of the heat preservation layer, the engineering quantity required by polyurethane heat preservation mortar in the heat preservation layer is counted in a layered mode after the heat preservation layer model is adjusted in thickness, the counting of the engineering quantity of the polyurethane heat preservation layer of the racetrack is completed, the manual calculation mode is completely overturned, and the problem that the engineering quantity calculation difficulty is large and inaccurate due to manual calculation is solved.

Description

Method and system for carrying out statistics on engineering quantity of polyurethane heat-insulating layer of racetrack by using BIM

Technical Field

The invention relates to the technical field of racetrack heat preservation construction, in particular to a method and a system for carrying out racetrack polyurethane heat preservation layer engineering quantity statistics by using BIM.

Background

The socialist market economy develops today, and the engineering cost industry is more and more emphasized, which is reflected in the aspects of social economy and life, namely the engineering cost is the unprecedented concern of government investment projects, enterprise investment projects, external capital projects, personal investment projects and engineering contractors. At present, no matter investment estimation, approximate calculation, budget and settlement are closely related to the engineering quantity, and no engineering cost exists independently of the engineering quantity, so that strong attention needs to be paid to basic calculation work which is extremely important in engineering cost management to determine and control the engineering cost. Under the era background of the vigorous development of the application of the BIM technology, the fusion of the traditional engineering cost and the BIM technology is a great trend and is also a necessary condition for making the fine engineering calculation. Various BIM modeling calculation amount software in the current market is in a hundred-flower buzz state, and is mainly developed and optimized for building construction engineering. In addition, due to the fact that the BIM modeling computation amount software of the current metallurgical industrial engineering, municipal engineering and the like has software technology development problems or software engineers do not deeply know relevant professional engineering specifications and rules and the like, the development of the functions of the professional engineering BIM modeling software is not thorough, and the actual use requirements of engineering participants cannot be met. Aiming at the problems, the purpose of refining the calculation amount is achieved by combining the functions of existing software with a professional atlas, drawing specifications and a flexible collusion combined modeling method, and the market use requirements are met.

At present, the high wall section of the snowmobile ski track is of a curved shell structure, and a polyurethane heat-insulating layer of the track is located on the outer contour and structural columns of the track. At present, the heat insulation layer constructed on the curved shell and the structural column can only finish the calculation of the engineering quantity in a complicated manual calculation mode, brings huge difficulty to the calculation of the engineering quantity, and is easy to miss calculation or repeat calculation. The bottom hand calculation mode causes unnecessary work volume and material loss for the project.

Disclosure of Invention

In view of the above, the invention provides a method and a system for calculating the engineering quantity of a polyurethane insulating layer of a track by using BIM, and aims to solve the problem that the existing track insulating layer can only calculate the engineering quantity in a manual calculation mode, so that the calculation of the engineering quantity is difficult and inaccurate.

On one hand, the invention provides a method for carrying out the statistics of the engineering quantity of a polyurethane heat-insulating layer of a racetrack by using BIM, which comprises the following steps: modeling the track according to a layered modeling mode to obtain a track model; layering heat preservation layers of the track model and endowing materials to the layers of the heat preservation layers; adjusting the thickness of the heat-insulating layer model at the polyurethane mortar support column according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the racetrack; and carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer.

Further, according to the method for counting the engineering quantity of the polyurethane heat-insulating layer of the racetrack by using the BIM, after the heat-insulating layer of the racetrack model is layered and materials are given to each layer of the heat-insulating layer, before the engineering quantity required by polyurethane heat-insulating mortar in the heat-insulating layer is counted in a layered manner, the method further comprises the following steps: marking the basic information and the preset thickening position of the heat-insulating layer in the track model to obtain the track model containing marking information; and determining the construction time point of the heat insulation layer and the information of the spraying and leveling equipment according to the marked basic information and the preset thickening position.

Further, according to the method for counting the engineering quantity of the polyurethane insulating layer of the racetrack by using the BIM, after the step of marking the basic information and the preset thickening position of the insulating layer, the method further comprises the following steps of: the method comprises the steps of utilizing a Rhion software to carry out modeling on a construction site according to a layered modeling mode to obtain a field model, connecting a track model chain containing marking information into the field model to obtain a track integration model, utilizing visualization advantages to determine a construction scheme of spraying a track heat-insulating layer, and carrying out procedure simulation on the construction scheme.

Further, according to the method for carrying out the statistics of the engineering quantity of the polyurethane heat-insulating layer of the racetrack by utilizing the BIM, each step is carried out in Rhion software.

Further, according to the method for carrying out the engineering quantity statistics of the polyurethane heat-insulating layer of the racetrack by utilizing the BIM, in the step of carrying out the engineering quantity statistics on the polyurethane heat-insulating mortar in the heat-insulating layer in a layering manner, the engineering quantity is subjected to the layering statistics by utilizing the detailed table function of the Rhion software GH parameter software.

The method for carrying out the statistics of the engineering quantity of the polyurethane heat-insulating layer of the racetrack by utilizing the BIM flexibly applies the prior function of the software by combining the continuous exploration test thinking with the software calculation mode, innovations are made on the modeling method, and by modeling the racetrack, layering the heat preservation layer, endowing materials to each layer of the heat preservation layer, adjusting the thickness of the heat preservation layer model, the statistics of the engineering quantity of the polyurethane heat-insulating layer of the racetrack is completed by carrying out the layered statistics of the engineering quantity required by the polyurethane heat-insulating mortar in the heat-insulating layer, the manual calculation mode is completely overturned, the problem that the engineering quantity calculation difficulty is large and inaccurate caused by the manual calculation is solved, a firm basis is laid for the calculation of the quantity in the later period of progress report, and a modeling thought is provided for software development, in addition, a BIM technical support basis is provided for construction fine management and a data information management platform.

On the other hand, the invention provides a system for carrying out the statistics of the engineering quantity of the polyurethane heat-insulating layer of the track by using BIM, which comprises the following steps: the track modeling module is used for modeling the track according to a layered modeling mode to obtain a track model; the material endowing module is used for layering the heat preservation layers of the track model and endowing materials to the layers of the heat preservation layers; the thickness adjusting module is used for adjusting the thickness of the heat-insulating layer model at the column of the polyurethane mortar support according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the racetrack; and the data statistics module is used for carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer.

Further, the above system for performing the statistics of the engineering quantity of the polyurethane insulation layer of the racetrack by using the BIM further comprises: the marking module is used for marking the basic information and the preset thickening position of the heat-insulating layer in the track model to obtain the track model containing marking information; and the equipment confirmation module is used for determining the construction time point of the heat insulation layer and the information of the jet floating equipment according to the marked basic information and the preset thickening position.

Further, the above system for performing the statistics of the engineering quantity of the polyurethane insulation layer of the racetrack by using the BIM further comprises: and the scheme determining module is used for modeling the construction site by utilizing the Rhion software according to a layered modeling mode to obtain a field model, accessing the track model chain containing the marking information into the field model to obtain a track integration model, determining a construction scheme for spraying the track insulating layer by utilizing the visualization advantage, and simulating the working procedures of the construction scheme.

Further, in the system for carrying out the statistics of the engineering quantity of the polyurethane heat-insulating layer of the track by using the BIM, all the modules are carried out by using Rhion software.

Further, in the system for carrying out the statistics of the engineering quantity of the polyurethane heat-insulating layer of the racetrack by using the BIM, the data statistics module is also used for carrying out the layered statistics of the engineering quantity by using the detailed table function of the GH parameter software of the Rhion software.

Because the system and the method are similar in principle, the system has the same technical effect as the method.

Drawings

Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:

FIG. 1 is a block diagram of a flow chart of a method for calculating the engineering quantity of a polyurethane insulation layer of a racetrack by using BIM according to an embodiment of the present invention;

FIG. 2 is a block diagram of another flow chart of a method for calculating the engineering quantity of a polyurethane insulation layer of a racetrack by using BIM according to an embodiment of the present invention;

FIG. 3 is a further flowchart of a method for performing statistics on engineering quantities of a polyurethane insulation layer of a racetrack according to an embodiment of the present invention;

fig. 4 is a block diagram of a system for performing statistics on engineering quantities of a polyurethane insulation layer of a racetrack according to the embodiment of the present invention.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art. It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

Referring to fig. 1, it is a block flow diagram of a method for performing statistics on engineering quantities of a polyurethane insulation layer of a racetrack by using BIM according to an embodiment of the present invention. As shown, the method comprises the following steps:

and a modeling step S1, modeling the track according to a layered modeling mode to obtain a track model.

Specifically, according to the structural design drawing of the track body, modeling is carried out on the track in a layered modeling mode, and a track model is obtained.

And a material giving step S2, wherein the heat preservation layer of the track model is layered, and materials are given to each layer of the heat preservation layer.

Specifically, according to the information of the polyurethane mortar heat-insulating layer in the structural design drawing, the heat-insulating layer of the track model is layered, and materials are given to each layer of the heat-insulating layer.

And a thickness adjusting step S3, adjusting the thickness of the heat-insulating layer model at the polyurethane mortar support column according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the track.

Specifically, according to the position spraying thickness layering of the polyurethane mortar heat-insulating layer, namely information such as the thickness of each layer of the polyurethane mortar heat-insulating layer at each different position, the thickness of the heat-insulating layer model of the polyurethane mortar support column, namely the support column of the track support, is adjusted, so that the heat-insulating layer model is matched with a design drawing.

And a data statistics step S4, wherein the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer is subjected to layered statistics.

Specifically, by using the detailed table function of the Rhion software GH parameter software, the polyurethane mortar heat-insulating layer can be calculated in a layering and layer-by-layer mode, namely, the manual calculation mode in the past is completely reversed, the engineering quantity calculation period is shortened, the calculation quality is improved, the requirement of fine management of current situation construction is met, and the required engineering quantity, such as the mortar quantity, of each material of the polyurethane mortar heat-insulating layer is obtained through statistical calculation.

Referring to fig. 2, it is a block diagram of another flow chart of the method for performing statistics on the engineering quantity of the polyurethane insulation layer of the racetrack by using BIM according to the embodiment of the present invention. As shown, the method comprises the following steps:

And a labeling step S5, labeling the basic information and the preset thickening position of the heat-insulating layer in the track model to obtain the track model containing labeling information.

Specifically, marking basic information and a preset thickening position, namely a special position of a polyurethane mortar heat-insulating layer in a Rhion model according to a BIM three-dimensional model, namely a track model, created according to a design drawing to obtain a track model containing marking information; wherein the basic information includes: the preset thickening position can be the position of the polyurethane mortar support column or the upper edge and the like needing thickening of the heat-insulating layer.

And an equipment confirmation step S6, wherein the construction time point of the heat insulation layer and the information of the spray leveling equipment are determined according to the marked basic information and the preset thickening position.

Specifically, time points and information of spraying and leveling equipment required by the polyurethane mortar heat-insulating layer are planned in advance.

Referring to fig. 3, it is a further flowchart of the method for performing statistics on the engineering quantity of the polyurethane insulation layer of the racetrack by using BIM according to the embodiment of the present invention. As shown, the method comprises the following steps:

And the scheme determining module S7 is used for modeling the construction site by utilizing the Rhion software according to a layered modeling mode to obtain a field model, connecting the track model chain into the field model to obtain a track integration model, determining a construction scheme for spraying the track insulating layer by utilizing the visualization advantages, and simulating the working procedures of the construction scheme.

Specifically, firstly, according to a construction site, modeling the construction site by utilizing Rhion software in a layered modeling manner to obtain a site model; then, accessing the track model chain containing the marking information into a field model to obtain a track integration model; and finally, determining a construction scheme of the sprayed racetrack insulating layer by utilizing the visualization advantage, and carrying out procedure simulation on the construction scheme.

In this embodiment, each step can be performed in Rhion software.

In conclusion, the method for counting the engineering quantity of the polyurethane insulation layer of the racetrack by using BIM provided by the embodiment, by combining continuous exploration test thinking and a software calculation mode, the existing software functions are flexibly applied, a modeling method is innovated, and by modeling the track, layering the heat preservation layer, endowing materials to each layer of the heat preservation layer, adjusting the thickness of the heat preservation layer model, the statistics of the engineering quantity of the polyurethane heat-insulating layer of the racetrack is completed by carrying out the layered statistics of the engineering quantity required by the polyurethane heat-insulating mortar in the heat-insulating layer, the manual calculation mode is completely overturned, the problem that the engineering quantity calculation difficulty is large and inaccurate caused by the manual calculation is solved, a firm basis is laid for the calculation of the quantity in the later period of progress report, and a modeling thought is provided for software development, in addition, a BIM technical support basis is provided for construction fine management and a data information management platform.

Referring to fig. 4, a block diagram of a system for performing statistics on engineering quantities of a polyurethane insulation layer of a racetrack by using BIM according to an embodiment of the present invention is shown. As shown, the system includes: the device comprises a track modeling module 100, a material endowing module 200, a thickness adjusting module 300, a data statistics module 400, a labeling module 500, an equipment confirming module 600 and a scheme determining module 700; the track modeling module 100 is configured to model a track in a layered modeling manner to obtain a track model; the material endowing module 200 is used for layering the heat preservation layers of the track model and endowing materials to the layers of the heat preservation layers; the thickness adjusting module 300 is used for adjusting the thickness of the heat-insulating layer model at the column of the polyurethane mortar support according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the racetrack; the data statistics module 400 is used for carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer; the marking module 500 is used for marking the basic information and the preset thickening position of the heat insulation layer in the track model to obtain the track model containing marking information; the equipment confirming module 600 is used for determining the construction time point of the insulating layer and the information of the spraying and floating equipment according to the marked basic information and the preset thickening position; the scheme determining module 700 is used for modeling the construction site by utilizing the Rhion software according to a layered modeling mode to obtain a field model, connecting the track model chain containing the marking information into the field model to obtain a track integration model, determining a construction scheme for spraying the track insulation layer by utilizing the visualization advantage, and simulating the working procedures of the construction scheme.

Preferably, each module is implemented by using Rhion software.

Further preferably, the data statistics module 400 is further configured to perform hierarchical statistics on the engineering quantity by using a list function of a GH parameter software of the rhinon software.

Because the system and the method in the embodiment are similar in principle, the relevant parts can be mutually referred, and meanwhile, the system has the same technical effect as the method.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. A method for carrying out statistics on the engineering quantity of a polyurethane heat-insulating layer of a racetrack by using BIM is characterized by comprising the following steps:

modeling the track according to a layered modeling mode to obtain a track model;

layering heat preservation layers of the track model and endowing materials to the layers of the heat preservation layers;

adjusting the thickness of the heat-insulating layer model at the polyurethane mortar support column according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the racetrack;

and carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer.

2. The method for calculating the engineering quantity of the polyurethane thermal insulation layer of the racetrack according to the claim 1, wherein after the thermal insulation layer of the racetrack model is layered and materials are given to each layer of the thermal insulation layer, and before the engineering quantity required by polyurethane thermal insulation mortar in the thermal insulation layer is calculated in a layered manner, the method further comprises the following steps:

marking the basic information and the preset thickening position of the heat-insulating layer in the track model to obtain the track model containing marking information;

and determining the construction time point of the heat insulation layer and the information of the spraying and leveling equipment according to the marked basic information and the preset thickening position.

3. The method for carrying out statistics on the engineering quantity of the polyurethane insulating layer of the racetrack according to the BIM of claim 2, wherein after the step of marking the basic information and the preset thickening position of the insulating layer, the method further comprises the following steps:

the method comprises the steps of utilizing a Rhion software to carry out modeling on a construction site according to a layered modeling mode to obtain a field model, connecting a track model chain containing marking information into the field model to obtain a track integration model, utilizing visualization advantages to determine a construction scheme of spraying a track heat-insulating layer, and carrying out procedure simulation on the construction scheme.

4. The method for the statistics of the engineering quantity of the polyurethane insulation layer of the racetrack by using the BIM as claimed in any one of claims 1 to 3, wherein each step is carried out in Rhion software.

5. The method for the statistics of the engineering quantity of the polyurethane thermal insulation layer of the racetrack according to claim 4,

and in the step of carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer, carrying out layered statistics on the engineering quantity by utilizing the detailed table function of a GH parameter software of the Rhion software.

6. A system for carrying out statistics on engineering quantity of a polyurethane heat-insulating layer of a track by utilizing BIM is characterized by comprising the following steps:

the track modeling module is used for modeling the track according to a layered modeling mode to obtain a track model;

the material endowing module is used for layering the heat preservation layers of the track model and endowing materials to the layers of the heat preservation layers;

the thickness adjusting module is used for adjusting the thickness of the heat-insulating layer model at the column of the polyurethane mortar support according to the spraying layering thickness of the polyurethane mortar heat-insulating layer at each position on the racetrack;

and the data statistics module is used for carrying out layered statistics on the engineering quantity required by the polyurethane thermal insulation mortar in the thermal insulation layer.

7. The system for carrying out statistics on the engineering quantity of the polyurethane insulation layer of the racetrack according to the BIM of claim 6, is characterized by comprising the following steps:

the marking module is used for marking the basic information and the preset thickening position of the heat-insulating layer in the track model to obtain the track model containing marking information;

and the equipment confirmation module is used for determining the construction time point of the heat insulation layer and the information of the jet floating equipment according to the marked basic information and the preset thickening position.

8. The system for the statistics of the engineering quantity of the polyurethane insulation layer of the racetrack according to the claim 7, which comprises:

and the scheme determining module is used for modeling the construction site by utilizing the Rhion software according to a layered modeling mode to obtain a field model, accessing the track model chain containing the marking information into the field model to obtain a track integration model, determining a construction scheme for spraying the track insulating layer by utilizing the visualization advantage, and simulating the working procedures of the construction scheme.

9. The system for track polyurethane insulation layer engineering quantity statistics by using BIM according to any one of claims 6 to 8, wherein each module is performed by using Rhion software.

10. The system for the statistics of the engineering quantity of the polyurethane thermal insulation layer of the racetrack according to claim 9,

and the data statistics module is also used for carrying out layered statistics on the engineering quantity by utilizing the list function of the GH parameter software of the Rhion software.